Climate-driven variability in the occurrence of major floods across North America and Europe

Hodgkins, Glenn A.; Whitfield, Paul H.; Burn, Donald H.; Hannaford, Jamie; Renard, Benjamin; Stahl, Kerstin; Fleig, Anne; Madsen, Henrik; Mediero, Luis; Korhonen, Johanna; Murphy, Conor; Wilson, Donna

doi:10.1016/j.jhydrol.2017.07.027

Cited by 140 publications

(114 citation statements)

References 70 publications

(70 reference statements)

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“…Peaks for the American River time series are apparent at 2.3 and 15 years and in the LBDA time series at approximately 8, 20, and 64 years. A detailed analysis of these time series is beyond the scope of this paper, but we note that the high amplitude and long time periods of the quasiperiodic oscillations they exhibit are consistent with analyses of LFV in other hydroclimate systems (Hodgkins et al, 2017;Kiem et al, 2002;Swierczynski et al, 2012;Woollings et al, 2014). A detailed analysis of these time series is beyond the scope of this paper, but we note that the high amplitude and long time periods of the quasiperiodic oscillations they exhibit are consistent with analyses of LFV in other hydroclimate systems (Hodgkins et al, 2017;Kiem et al, 2002;Swierczynski et al, 2012;Woollings et al, 2014).…”

Section: Planning Decisions Are Made With Finite Horizonssupporting

confidence: 73%

Robust Adaptation to Multiscale Climate Variability

2019

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The assessment and implementation of structural or financial instruments for climate risk mitigation requires projections of future climate risk over the operational life of each proposed instrument. A point often neglected in the climate adaptation literature is that the physical sources of predictability differ between projects with long and short planning periods: While historical and paleo climate records emphasize low-frequency modes of variability, anthropogenic climate change is expected to alter their occurrence at longer time scales. In this paper we present a set of stylized experiments to assess the uncertainties and biases involved in estimating future climate risk over a finite future period, given a limited observational record. These experiments consider both quasi-periodic and secular change for the underlying risk, as well as statistical models for estimating this risk from an N-year historical record. The uncertainty of IPCC-like future scenarios is considered through an equivalent sample size N. The relative importance of estimating short-or long-term risk depends on the investment life M. Shorter design lives are preferred for situations where interannual to decadal variability can be successfully identified and predicted, highlighting the importance of sequential investment strategies for adaptation. Key Points: • Quasi-periodic and secular climate signals, with different identifiability and predictability, control future uncertainty and risk • Adaptation strategies must consider how uncertainties in risk projections influence success of decision pathways • Stylized experiments reveal how bias and variance of climate risk projections influence risk mitigation over a finite planning period Supporting Information: • Supporting Information S1

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Section: Planning Decisions Are Made With Finite Horizonssupporting

confidence: 73%

Robust Adaptation to Multiscale Climate Variability

2019

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“…Ward et al (2016) and Emerton et al (2017) have previously demonstrated the role of ENSO in modulating global floods. In addition, Hodgkins et al (2017) demonstrated recently that AMO has a significant negative (positive) relationship with 25-and 50-year flood occurrence for large (medium) catchments in North America (Europe).…”

Section: Millionsmentioning

confidence: 96%

Recent trends in the frequency and duration of global floods

2018

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Abstract. Frequency and duration of floods are analyzed using the global flood database of the Dartmouth Flood Observatory (DFO) to explore evidence of trends during 1985-2015 at global and latitudinal scales. Three classes of flood duration (i.e., short: 1-7, moderate: 8-20, and long: 21 days and above) are also considered for this analysis. The nonparametric Mann-Kendall trend analysis is used to evaluate three hypotheses addressing potential monotonic trends in the frequency of flood, moments of duration, and frequency of specific flood duration types. We also evaluated if trends could be related to large-scale atmospheric teleconnections using a generalized linear model framework. Results show that flood frequency and the tails of the flood duration (long duration) have increased at both the global and the latitudinal scales. In the tropics, floods have increased 4-fold since the 2000s. This increase is 2.5-fold in the north midlatitudes. However, much of the trend in frequency and duration of the floods can be placed within the long-term climate variability context since the Atlantic Multidecadal Oscillation, North Atlantic Oscillation, and Pacific Decadal Oscillation were the main atmospheric teleconnections explaining this trend. There is no monotonic trend in the frequency of short-duration floods across all the global and latitudinal scales. There is a significant increasing trend in the annual median of flood durations globally and each latitudinal belt, and this trend is not related to these teleconnections. While the DFO data come with a certain level of epistemic uncertainty due to imprecision in the estimation of floods, overall, the analysis provides insights for understanding the frequency and persistence in hydrologic extremes and how they relate to changes in the climate, organization of global and local dynamical systems, and country-scale socioeconomic factors.

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“…Banasik et al 2013;Ilnicki et al 2014;Kędra 2017;Miler 2015;Somorowska 2017) or small regions (Niedźwiedź et al 2015;Ruiz-Villanueva et al 2016;Sen and Niedzielski 2010), with one notable exception of Wrzesiński and Sobkowiak (2018) who analysed long-term changes (but not trends) in flow regime of 159 flow gauges with a good geographical coverage in Poland. Polish rivers were not included in several pan-European (Hannaford et al 2013;Stahl et al 2010) or global (Hodgkins et al 2017) studies on trend detection, perhaps due to restrictive data sharing policy . In summary, a need for a comprehensive trend detection study for Polish river flows is well motivated.…”

Section: Introductionmentioning

confidence: 99%

Trend detection in river flow indices in Poland

2018

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The issue of trend detection in long time series of river flow records is of vast theoretical interest and considerable practical relevance. Water management is based on the assumption of stationarity; hence, it is crucial to check whether taking this assumption is justified. The objective of this study is to analyse long-term trends in selected river flow indices in small-and medium-sized catchments with relatively unmodified flow regime (semi-natural catchments) in Poland. The examined indices describe annual and seasonal average conditions as well as annual extreme conditions-low and high flows. The special focus is on the spatial analysis of trends, carried out on a comprehensive, representative data set of flow gauges. The present paper is timely, as no spatially comprehensive studies (i.e. covering the entire Poland or its large parts) on trend detection in time series of river flow have been done in the recent 15 years or so. The results suggest that there is a strong random component in the river flow process, the changes are weak and the spatial pattern is complex. Yet, the results of trend detection in different indices of river flow in Poland show that there exists a spatial divide that seems to hold quite generally for various indices (annual, seasonal, as well as low and high flow). Decreases of river flow dominate in the northern part of the country and increases usually in the southern part. Stations in the central part show mostly 'no trend' results. However, the spatial gradient is apparent only for the data for the period 1981-2016 rather than for 1956-2016. It seems also that the magnitude of increases of river flow is generally lower than that of decreases.

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Climate-driven variability in the occurrence of major floods across North America and Europe

Cited by 140 publications

References 70 publications

Robust Adaptation to Multiscale Climate Variability

Robust Adaptation to Multiscale Climate Variability

Recent trends in the frequency and duration of global floods

Trend detection in river flow indices in Poland

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